EFFICIENT 3D ELECTROMAGNETIC MODELLING IN THE PRESENCE OF ANISOTROPIC CONDUCTIVE MEDIA, USING INTEGRAL EQUATIONS

Show simple item record

dc.contributor.author Fang S.
dc.contributor.author Gao G.-z.
dc.contributor.author Torres-Verdín C.
dc.date.accessioned 2024-09-14T06:08:22Z
dc.date.available 2024-09-14T06:08:22Z
dc.date.issued 2006
dc.identifier https://www.elibrary.ru/item.asp?id=29553463
dc.identifier.citation Exploration Geophysics, 2006, 37, 3, 239-244
dc.identifier.issn 0812-3985
dc.identifier.uri https://repository.geologyscience.ru/handle/123456789/45160
dc.description.abstract We present a novel technique to simulate numerically the measurements performed by a borehole induction-logging tool in 3D anisotropic rock formations. The simulations are based on an integral equation formulation. Previously, such a formulation was considered impractical for solving large-scale problems due to the resulting large full matrix. To overcome this difficulty, we assume a uniform background model and make use of a uniform grid whereupon there is no need to construct explicitly all of the entries of the full Green's function matrix. Using a uniform background model, the entries of the corresponding electric and magnetic Green's tensors are relatively easy to calculate. In the presence of a uniform grid (not necessarily cubic), it is only necessary to calculate the first row of the resulting electric Green's function matrix. Further, because the matrix is block Toeplitz, it can be rewritten into a block circulant form, and therefore matrix-vector multiplication can be efficiently performed with two FFTs and one inverse FFT. This strategy reduces the computation cost from O(N ´ N) to O(N ´ log2N). In addition to the substantial computer savings, the FFT technique also substantially reduces memory storage requirements because only the first row and the first column in the block Toeplitz matrix are needed to perform the computations of the remaining entries of the matrix. Numerical simulations of the measurements performed with an induction tool in dipping and anisotropic rock formations are benchmarked against accurate 3D finite-difference and 1D codes. These benchmark exercises show that the newly developed integral-equation algorithm produces accurate and efficient simulations for a variety of borehole and formation conditions. © 2006, CSIRO. All rights reserved.
dc.subject ANISOTROPY
dc.subject ELECTROMAGNETIC
dc.subject INDUCTION TOOL
dc.subject INTEGRAL EQUATION
dc.subject NUMERICAL SIMULATION
dc.title EFFICIENT 3D ELECTROMAGNETIC MODELLING IN THE PRESENCE OF ANISOTROPIC CONDUCTIVE MEDIA, USING INTEGRAL EQUATIONS
dc.type Статья
dc.identifier.doi 10.1071/EG06239


Files in this item

This item appears in the following Collection(s)

  • ELibrary
    Метаданные публикаций с сайта https://www.elibrary.ru

Show simple item record